Short-term treatment with estrone oleate in liposomes (Merlin-2) does not affect the expression of the ob gene in Zucker obese rats.

Young female Zucker fa/fa rats of 370-430 g were implanted with osmotic minipumps releasing 3.5 micromol/day-kg of estrone oleate in liposomes (Merlin-2) into the bloodstream for up to 14 days. Merlin-2 induced a sustained loss of appetite, and a decrease in body weight of 3.5%, which contrasts with the 8.2% increase in controls during the period studied. Plasma insulin, glucose and urea decreased, and liver glycogen increased with Merlin-2 treatment. Plasma ACTH and corticosterone increased to a maximum at the end of the experiment. The expression of the ob gene in adipose tissue was unchanged, and plasma leptin levels were also unchanged by treatment. Estrone levels increased more than 1500-fold, and estrone oleate rose 100-fold during treatment. The fact that estrone oleate had no effect on the leptin levels or expression in obese rats, in contrast with the marked inhibition observed in the lean suggests that the functionality of the leptin receptor is essential for estrone oleate inhibition of the ob gene. This also suggests that leptin may control ob gene expression in white adipose tissue and that estrone oleate may activate this process. The slimming effect of estrone oleate is, thus, not directly dependent on leptin, since both normoleptinemic and hyperleptinemic animals lose fat following treatment nor are the effects on appetite and energy expenditure mediated by leptin. However, leptin levels and the expression of the ob gene are directly linked with estrone oleate function. A possible involvement of leptin in estrone oleate action is postulated. The results support the participation of estrone oleate in the control of body weight and hint at the complexity of its regulation by leptin and glucocorticoids.

Oleoyl-estrone treatment affects the ponderostat setting differently in lean and obese Zucker rats.

OBJECTIVE: To determine whether the slimming effects of treatment with oleoyl-estrone (OE) in liposomes of normal and obese rats are permanent, or disappear as soon as the treatment with the drug ceased. This study was devised to gain further knowledge on the postulated role of OE as a ponderostat signal, evaluating whether (in addition) it can lower the ponderostat setting of the rat. DESIGN: The rats were infused for 14d (using osmotic minipumps) with oleoyl-estrone in liposomes at a dose of 3.5 micromol/kg x d, and were studied up to one month after the treatment ceased. SUBJECTS: Young adult lean controls (CL) or treated (TL) and obese controls (CO) or treated (TO) Zucker rats. MEASUREMENTS: Energy balance, blood glucose, liver glycogen, plasma insulin, leptin corticosterone, ACTH and estrone (free and total) concentrations, and expression of the OB gene in white adipose tissue (WAT). RESULTS: The loss of body weight caused by OE was recovered quickly in the TO, which gained weight at the same rate as the CO. TL rats, however remained at the low weight attained for one month after the treatment ceased. However, no differences were observed in calculated energy expenditure (EE) between the TL and TC rats once treatment had stopped. In TL and TO rats, liver glycogen concentrations decreased to normal shortly after treatment ceased, and leptin expression and concentrations remained normal and unchanged after the end of OE treatment. In TO rats, plasma glucose, insulin and leptin were lower than in the CO. Total estrone concentrations decreased rapidly in TL rats and more slowly in the TO, and free estrone followed a similar pattern. CONCLUSION: Continuous infusion of liposomes loaded with OE resulted in a decreased energy intake (EI), maintenance of EE and the utilization of body fat reserves in lean and obese rats alike. This process ended in obese rats as soon as the infusion ceased, so that even when the levels of free and total estrone in plasma remained high, there was a marked (and relatively fast) shift toward the basal situation, which translated into an increase in EI, maintenance of estimated EE and a marked buildup of energy stores. In lean rats, the effects of OE on leptin concentrations and OB gene expression persisted after infusion ended.

Oleoyl-estrone does not alter hypothalamic neuropeptide Y in Zucker lean and obese rats.

Female Zucker lean and obese rats were treated for 14 days with 3.5 micromol/kg oleoyl-estrone (OE) in liposomes (Merlin-2). After 0, 3, 6, 10, and 14 days of treatment, the rats were killed and hypothalamic nuclei (lateral preoptic, median preoptic, paraventricular, ventromedial and arcuate) were used for neuropeptide Y (NPY) radioimmunoassay. In 14 days, OE decreased food intake by 26% in lean and 38% in obese rats and energy expenditure by 6% in lean and 47% in obese rats; the body weight gap between controls and treated rats becoming -17.8% of initial b.wt. in the lean and -13.6% in the obese rats. Obese rats showed higher NPY levels in all the nuclei than the lean rats. Despite a negative energy balance and decreased food intake, there were practically no changes in NPY with OE treatment. The results indicate that oleoyl-estrone does not act through NPY in its control of either food intake or thermogenesis in lean and genetically obese rats.

Zucker obese rats are insensitive to the CRH-increasing effect of oleoyl-estrone.

Adult female Zucker lean and obese rats were treated for 14 days with 3.5 nm/kg oleoyl-estrone (OE) in liposomes (Merlin-2) through continuous i.v. injection with osmotic minipumps. Rat wt. and food intake were measured daily. On days 0, 3, 6, 10, and 14, groups of rats were killed and their hypothalamic nuclei [lateral preoptic (LPO), median preoptic (MPO), paraventricular (PVN), ventromedial (VMH), and arcuate (ARC)] were dissected, homogenized, and used for the measurement of corticosterone-releasing hormone (CRH) by radioimmunoassay. The OE treatment decreased food intake by 67.4% in lean and 62.6% in obese rats (means for 14 days). Body wt. decreased steadily in lean and obese rats, the gap between controls and treated rats becoming 11.5% of initial body wt. in the lean and 12.4% in the obese. The levels of CRH in the ARC nucleus were at least 10-fold higher than in the other nuclei. No changes in CRH were observed in any of the nuclei of obese rats, with levels up to day 6 similar to those of lean rats. In the lean rats, the LPO and ARC nuclei showed peaks on day 10, while the MPO showed no changes and the PVN and VMH nuclei showed a progressive increase, to a maximum at the end of the study (day 14). This contrasted with the peak of plasma adrenocorticotropic hormone (ACTH) and corticosterone (day 6 in lean and day 14 in obese rats). There was a definite lack of correlation between the plasma levels of these two hormones and the levels of CRH in the hypothalamic nuclei, and between the latter and the decreases in appetite in the rats. The loss of appetite induced by OE is not necessarily mediated by CRH, because the obese rats show an intense decrease in voluntary food intake but their hypothalamic nuclei CRH levels do not change at all. Hypothalamic nuclei CRH does not, necessarily, mediate the rise in glucocorticoids induced by OE treatment, because this is observed in lean and obese rats, lean rats increases being mismatched with those of hypothalamic CRH. The OE induced changes in hypothalamic CRH require a fully functional leptinergic pathway, because it is not observed in Zucker fa/fa rats lacking a working leptin receptor. This--indirectly--shows that leptin is needed for its synthesis or modulation.

Effect of oleoyl-estrone administration on corticosterone binding to tissues of lean and obese Zucker rats.

A group of female Zucker lean and obese rats was treated with 3.5 micromol/day kg of oleoyl-estrone in liposomes (OE) injected i.v. continuously for 14 days with inserted osmotic minipumps. Samples of liver were extracted on days 0, 3, 6, 10 and 14 and the expression of corticosterone-binding globulin (CBG) was determined by Northern blot. On the same dates, the total binding capacity of plasma, liver, periovaric white adipose tissue (WAT) and subcutaneous WAT was also determined using tritium-labelled corticosterone. Treatment with OE resulted in diminished CBG gene expression in the liver, this being more marked in the obese rats. Basal (time 0) corticosterone binding was higher in the plasma, liver and WAT of lean rats. Treatment with OE resulted in a gradual and general loss of binding capacity in the plasma and all tissues studied, for lean and obese rats alike. Since CBG decreases may result in enhanced glucocorticoid availability (and effects), the global decrease in corticosterone binding observed can be interpreted as a counteractive response to the energy imbalance elicited by OE.

Differential short-term distribution of estrone and oleoyl-estrone administered in liposomes to lean and obese Zucker rats.

Thirteen-week-old female Zucker lean (Fa/Fa) and obese (fa/fa) rats were injected through a cannula inserted in the left jugular vein with 1 mL/kg of 3H-labeled oleoyl-estrone in liposomes (Merlin-2) (i.e., 670 fmol, 84 kBq). The rats were killed 10 minutes later and dissected. The presence of intact or hydrolyzed oleoyl-estrone was later determined in all samples. The pattern of distribution of estrone was quite different from that of oleoyl-estrone both in rats that were lean and in those that were obese. Estrone was better retained by white adipose tissue than oleoyl-estrone. Liver, spleen, and lungs accumulated more oleoyl-estrone and split part of it, from 4.7% (lung, obese) to 27% (liver, lean). The overall high retention of estrone by the rat tissues results in its very low circulating levels. The fast splitting of liposome-carried oleoyl-estrone by most tissues (up to more than 67% by intestine and skin of lean rats) may help explain the rise in blood free estrone. The differences between lean and obese Zucker rats are mainly quantitative in the case of estrone, the main differences being found in blood and adipose tissues. However, when we compare the data for oleoyl-estrone, the differences cannot be dismissed simply as due to differences in body size or the extent of fat deposits. A large portion of the label remained in the blood of the rats that were obese but not in those that were lean, the tissues of which took up more label. Brown adipose tissue shows a fair affinity for oleoyl-estrone in the rats that were lean but practically does not retain label in the rats that were obese, suggesting that oleoyl-estrone may have a direct effect on brown adipose tissue. The decreased uptake of oleoyl-estrone in rats that were obese shows that the mechanism regulating the turnover or disposal of this signal is altered in this type of genetic obesity.

Effect of adrenalectomy on the slimming activity of liposome-carried oleoyl-estrone in the rat.

OBJECTIVE: To determine the extent of glucocorticoid counter-regulatory control in the slimming action of oleoylestrone. DESIGN: Control and adrenalectomized rats were subjected to a seven-day treatment with 3.5 micromol/kg/d oleoylestrone in liposomes injected i.v. continuously by implanted osmotic minipumps. SUBJECTS: Sham-operated control and adrenalectomized lean Zucker rats. MEASUREMENTS: Body weight and food intake; plasma glucose, urea, insulin, leptin and corticosterone; liver glycogen. RESULTS: Treatment with oleoyl-estrone resulted in decreases in body weight and in food intake, as well as in circulating glucose, insulin and leptin. Combined adrenalectomy and oleoyl-estrone treatment resulted in a loss of almost 15% body weight in only seven days, with a severe drop in circulating glucose and insulin, almost total disappearance of plasma leptin and liver glycogen and a 3-fold rise in circulating urea. Food intake decreased sharply, which resulted in the exhaustion of energy reserves. CONCLUSION: The results presented here, strongly support the hypothesis that glucocorticoids play an important role in the modulation of oleoyl-estrone-induced imbalance of energy intake and expenditure. The large effect of oleoyl-estrone on glucose, glycogen- and protein-derived (urea levels) energy in adrenalectomized rats, provides more evidence for the assumed protective role of glucocorticoids against the oleoyl-estrone-induced net loss of energy reserves. The results also show the powerful destabilizing effects of unchecked oleoyl-estrone on energy balance.

Effect of the slimming agent oleoyl-estrone in liposomes on the body weight of Zucker obese rats.

OBJECTIVE: To determine whether the mechanisms by which estrone acyl-esters carried by lipoproteins induce the loss of body fat can affect Zucker fa/fa rats, since they are hyperphagic and could not eliminate excess energy through thermogenesis, two aspects essential for the slimming effect of oleoyl-estrone in normal rats. DESIGN: The rats were infused for 28 d (osmotic minipumps) with oleoyl-estrone in liposomes (Merlin-2) at a dose of 3.5 mmol/day.kg. SUBJECTS: Lean (L) and obese (O) Zucker rats. MEASUREMENTS: Body weight changes. Oxygen consumption, body composition (water, lipid, protein), nitrogen balance, plasma chemistry. RESULTS: Treatment resulted in loss of body weight: 12.0% (28 g) L, 9.4% (34 g) O, mainly due to fat: 37.5% (10.8 g) L, 11.7% (15.5 g) O and water, preventing further increases in body weight and fat storage. Untreated rats increased their body weight: 10.5% (24 g) L, 32.2% (101 g) O and lipid stores: 20.3% (5.9 g) L, 39.8% (49.0 g) O, making the differences more marked. On day 28, glucose levels were maintained in all groups; in L, triacylglycerols increased and total cholesterol decreased; O showed no changes in plasma composition. In all rats, food intake decreased with treatment, and heat production (oxygen consumption) was unchanged (L) or slightly decreased (O). Energy expenditure per unit of fat-free mass remained unchanged. Protein balance was maintained in all groups; slimming was achieved without loss of body protein. CONCLUSION: Treatment of genetically obese rats with oleoyl-estrone in liposomes (Merlin-2) results in sustained loss of body weight-mainly lipid, sparing protein-for up to 28 d, essentially preventing further increase in body weight and accumulation of lipid and protein. This is achieved through lower food intake and relatively small changes (if any) in energy expenditure.

Short-term treatment with oleoyl-oestrone in liposomes (Merlin-2) strongly reduces the expression of the ob gene in young rats.

Young female rats of 160-180 g were implanted with osmotic minipumps releasing 3.0 micromol/day per kg of oleoyl-oestrone in liposomes (Merlin-2) into the bloodstream for up to 14 days. Merlin-2 induced a loss of appetite in the first days, later recovered, and a decrease in body weight of 7%, which contrasts with the 15% increase in controls during the 2-week period. Neither plasma glucose nor urea was affected by treatment, but liver glycogen increased by 50% in 14 days. Insulin decreased slightly with Merlin-2 treatment. Plasma corticotropin (ACTH) and corticosterone showed a transient increase by day 6 of treatment. The expression of the ob gene in adipose tissue fell during the period studied to practically nil on day 14; circulating leptin levels decreased more than 70% from day 1 to day 14. Oestrone levels increased from 0.3 nM (controls) to a maintained 40-60 nM level for the rest of the experiment. Oleoyl-oestrone levels first increased 4-fold, to decrease again to the initial levels on day 10, increasing later to 100-fold on day 14. The three phases observed in food intake, weight loss and oleoyl-oestrone levels match fairly well, which supports the direct involvement of oleoyl-oestrone in body-weight control. However, the control of oleoyl-oestrone levels seems to be mediated in part by corticosterone. The practical disappearance of leptin synthesis coincides with the massive accumulation of oleoyl-oestrone in plasma. The results presented suggest the involvement of oleoyl-oestrone in the main mechanisms of control of body weight and its regulation by glucocorticoids and leptin.

Transgenic plants: an emerging approach to pest control.

Insect pests are a major cause of damage to the world's commercially important agricultural crops. Current strategies aimed at reducing crop losses rely primarily on chemical pesticides. Alternatively transgenic crops with intrinsic pest resistance offer a promising alternative and continue to be developed. The first generation of insect-resistant transgenic plants are based on insecticidal proteins from Bacillus thuringiensis (Bt). A second generation of insect-resistant plants under development include both Bt and non-Bt proteins with novel modes of action and different spectra of activity against insect pests.

The Bacillus thuringiensis vegetative insecticidal protein Vip3A lyses midgut epithelium cells of susceptible insects.

The Vip3A protein is a member of a newly discovered class of vegetative insecticidal proteins with activity against a broad spectrum of lepidopteran insects. Histopathological observations indicate that Vip3A ingestion by susceptible insects such as the black cutworm (Agrotis ipsilon) and fall armyworm (Spodoptera frugiperda) causes gut paralysis at concentrations as low as 4 ng/cm2 of diet and complete lysis of gut epithelium cells resulting in larval death at concentrations above 40 ng/cm2. The European corn borer (Ostrinia nubilalis), a nonsusceptible insect, does not develop any pathology upon ingesting Vip3A. While proteolytic processing of the Vip3A protein by midgut fluids obtained from susceptible and nonsusceptible insects is comparable, in vivo immunolocalization studies show that Vip3a binding is restricted to gut cells of susceptible insects. Therefore, the insect host range for Vip3A seems to be determined by its ability to bind gut cells. These results indicate that midgut epithelium cells of susceptible insects are the primary target for the Vip3A insecticidal protein and that their subsequent lysis is the primary mechanism of lethality. Disruption of gut cells appears to be the strategy adopted by the most effective insecticidal proteins.

Vip3A, a novel Bacillus thuringiensis vegetative insecticidal protein with a wide spectrum of activities against lepidopteran insects.

A novel vegetative insecticidal gene, vip3A(a), whose gene product shows activity against lepidopteran insect larvae including black cutworm (Agrotis ipsilon), fall armyworm (Spodoptera frugiperda), beet armyworm (Spodoptera exigua), tobacco budworm (Heliothis virescens), and corn earworm (Helicoverpa zea) has been isolated from Bacillus thuringiensis strain AB88. VIP3-insecticidal gene homologues have been detected in approximately 15% of Bacillus strains analyzed. The sequence of the vip3A(b) gene, a homologue of vip3A(a) isolated from B. thuringiensis strain AB424 is also reported. Vip3A(a) and (b) proteins confer upon Escherichia coli insecticidal activity against the lepidopteran insect larvae mentioned above. The sequence of the gene predicts a 791-amino acid (88.5 kDa) protein that contains no homology with known proteins. Vip3A insecticidal proteins are secreted without N-terminal processing. Unlike the B. thuringiensis 5-endotoxins, whose expression is restricted to sporulation, Vip3A insecticidal proteins are expressed in the vegetative stage of growth starting at mid-log phase as well as during sporulation. Vip3A represents a novel class of proteins insecticidal to lepidopteran insect larvae.

Cloning of a cryV-type insecticidal protein gene from Bacillus thuringiensis: the cryV-encoded protein is expressed early in stationary phase.

A CryV-type protein (CGCryV) has been isolated from supernatant fluids of Bacillus thuringiensis AB88 cultures. Previous reports have suggested the cryptic nature of the cryV-type genes on the basis of the absence of CryV-type proteins in parasporal crystals. The CryV-type protein reported here is expressed early in stationary phase, and evidence indicates that it is an exported protein. Analysis of the deduced protein sequence from this gene reveals the presence of an N-terminal domain that likely acts as a signal peptide. The CGCryV protein is the first reported case of a delta-endotoxin being a secreted protein, which may influence the biological relevance of these proteins.

Cloning and characterization of a maize pollen-specific calcium-dependent calmodulin-independent protein kinase.

A calcium-dependent calmodulin-independent protein kinase (CDPK) has been cloned from maize (Zea mays). The sequence predicts a 550-amino acid (predicted molecular mass is 60 kDa) protein with two major functional domains: an N-terminal catalytic domain highly homologous to protein kinases and a C-terminal domain resembling calmodulins. Northern analysis shows that the expression of the maize CDPK gene is pollen specific and that its transcription is restricted to late stages of pollen development. Western blots reveal a major abundance of CDPK protein at the stage of pollen germination. In vitro germination and pollen tube growth are impaired upon addition of a calmodulin antagonist (calmidazolium), CDPK inhibitors (W-7), and antisense oligonucleotides directed against CDPK mRNA. These observations indicate that the function of the pollen-specific maize CDPK protein is required for germination and pollen tube growth.

Plant activating sequences: positively charged peptides are functional as transcriptional activation domains.

Plant sequences that act as transcriptional activation domains in yeast as well as in plants have been isolated by genetic selection in yeast. The selection was based on the reconstitution of a functional GAL4 transcriptional activator. Since the peptides show no homology with reported activation domains, they represent a new class of activating sequences. The sequence P1, which is 10 amino acids long, is the shortest functional activation domain reported. A cDNA that encodes the P14 class (peptides P14-P18) activating sequence have been cloned. The protein exhibits strong homology (higher than 50% amino acid identity) with the BBC1-related sequences, a highly conserved family of basic proteins containing nuclear localization signals. The P14 and P15 peptides are the most effective plant activating sequences. The P14 and P15 peptides are highly hydrophilic, positively charged and mostly unstructured. These properties are at odds with the ones usually found in known activation domains.